KR20190120927A - Elliptical polarizing plate and organic light emitting device - Google Patents

Abstract

The present application relates to an elliptical polarizing plate, and to an organic light emitting device. The elliptical polarizing plate of the present application may provide an ultra-high visibility elliptical polarizing plate having excellent reflection characteristics and color characteristics at the side surfaces as well as the front surface, and the organic light emitting device including the elliptical polarizing plate. The elliptical polarizing plate sequentially includes a linear polarizer, a first retardation film, a second retardation film, a third retardation film, and a fourth retardation film.

Description

Elliptical Polarizer and Organic Light Emitting Device {ELLIPTICAL POLARIZING PLATE AND ORGANIC LIGHT EMITTING DEVICE}

The present application relates to an elliptical polarizer and an organic light emitting device.

Recently, there is a demand for weight reduction and thinning of a monitor or a television, and according to such a demand, an organic light emitting device (OLED) has attracted attention. The organic light emitting device is a self-luminous display device that emits light by itself and thus does not require a separate backlight, thereby reducing thickness and advantageously implementing a flexible display device.

On the other hand, the organic light emitting device may reflect external light by the metal electrode and the metal wiring formed on the organic light emitting display panel, and the visibility and the contrast ratio may be degraded by the reflected external light, thereby degrading display quality. As in Patent Document 1, a circular polarizer may be attached to one surface of an organic light emitting display panel to reduce the leakage of the reflected external light to the outside.

However, the currently developed circular polarizer has a strong viewing angle dependency, and thus has a problem in that visibility is reduced due to a decrease in antireflection performance toward the side.

Republic of Korea Patent Publication No. 2009-0122138

The present application provides an ultra-high visibility ellipsoidal polarizing plate having excellent reflection characteristics and color characteristics in front as well as side and an organic light emitting device including the same.

The present application relates to an elliptical polarizer. 1 exemplarily shows a structure of an elliptical polarizing plate of the present application. As shown in FIG. 1, the elliptical polarizing plate sequentially processes the linear polarizer 50, the first retardation film 10, the second retardation film 20, the third retardation film 30, and the fourth retardation film 40. It can be included as.

In the present specification, the polarizer means an element that exhibits selective transmission and absorption characteristics with respect to incident light. The polarizer may transmit, for example, light oscillating in one direction from incident light oscillating in various directions, and absorb light oscillating in the other direction.

In the present specification, the linear polarizer refers to a polarizer that is linearly polarized light in which selectively transmitted light vibrates in one direction and linearly polarized light in which selectively absorbing light vibrates in a direction perpendicular to the vibration direction of the linearly polarized light.

As the linear polarizer, for example, a polarizer in which iodine is impregnated in a polymer stretched film such as a PVA stretched film or a liquid crystal polymerized in an oriented state is used as a host, and anisotropic dyes arranged in accordance with the alignment of the liquid crystal are used as a guest. The guest-host polarizer may be used, but is not limited thereto.

According to the exemplary embodiment of the present application, a PVA stretched film may be used as the linear polarizer. The transmittance to polarization degree of the linear polarizer may be appropriately adjusted in consideration of the purpose of the present application. For example, the transmittance of the linear polarizer may be 42.5% to 55%, and the degree of polarization may be 65% to 99.9997%.

When defining angles in this specification, when using terms such as vertical, horizontal, orthogonal or parallel, this means substantially vertical, horizontal, orthogonal or parallel in the range that does not impair the desired effect, for example , Error including manufacturing error or variation. For example, each of the above cases may include an error within about ± 15 degrees, an error within about ± 10 degrees or an error within about ± 5 degrees.

In the present specification, the retardation film may mean an element capable of converting incident polarization by controlling birefringence as an optical “anisotropic” film. In the present specification, unless noted otherwise, the x-axis refers to a direction parallel to the in-plane slow axis of the retardation film, and the y-axis refers to a direction parallel to the in-plane fast axis of the retardation film. The z axis means the thickness direction of the retardation film. The x and y axes may be perpendicular to each other in plane. While describing the optical axis of the retardation film herein, unless otherwise specified, the slow axis means. When the retardation film includes a rod-shaped liquid crystal molecule, the slow axis may mean a long axis direction of the rod shape, and when the retardation film includes a disc-shaped liquid crystal molecule, the slow axis may mean a normal direction of the disc shape.

In the present specification, the Nz value of the retardation film is calculated by the following Equation 1.

[Equation 1]

Nz = (nx-nz) / (nx-ny)

In the present specification, a retardation film satisfying the following general formula 1 may be referred to as a so-called + C plate.

In the present specification, a retardation film satisfying the following general formula 2 may be referred to as a so-called + B plate.

In the present specification, a retardation film satisfying the following general formula (3) may be referred to as a so-called -B plate.

In the present specification, a retardation film satisfying the following general formula (4) may be referred to as a so-called + A plate.

[Formula 1]

nx = ny <nz

[Formula 2]

ny <nx ≠ nz

[Formula 3]

nx> ny> nz

[Formula 4]

nx> ny = nz

In the present specification, the retardation (Rth) in the thickness direction of the retardation film is calculated by the following formula (2).

In the present specification, the surface retardation (Rin) of the retardation film is calculated by the following Equation 3.

[Formula 2]

Rth = (nz-ny) × d

[Equation 3]

Rin = (nx-ny) × d

In Equations 1 to 3 and 1 to 4, nx, ny, and nz are refractive indexes in the x-axis, y-axis, and z-axis directions defined above, respectively, and d is the thickness of the retardation film.

In the present specification, the reverse wavelength dispersion may mean a characteristic satisfying Equation 4 below, and the normal wavelength dispersion may mean a characteristic satisfying Equation 5 below. Flat wavelength dispersion may mean a property satisfying the following Equation 6.

[Equation 4]

R (450) / R (550) <R (650) / R (550)

[Equation 5]

R (450) / R (550)> R (650) / R (550)

[Equation 6]

R (450) / R (550) = R (650) / R (550)

In the present specification, the refractive index of the retardation film is described, and unless otherwise specified, the refractive index with respect to light having a wavelength of about 550 nm. In the above description, R (λ) may mean a planar phase difference or a thickness direction phase difference with respect to λnm light.

The present application may implement an elliptical polarizing plate of super visibility from the front as well as the side by adjusting the optical properties of the first retardation film, the second retardation film, the third retardation film and the fourth retardation film. As one example, the elliptical polarizing plate of the present application may have a maximum value of color deviation at an inclination angle of 40 degrees and an azimuth of 45 degrees or 135 degrees of less than 2.8, less than 2.7, less than 2.6, less than 2.5, or less than 2.4. Color deviation herein calculate the elliptically polarizing plate is in the embodiment of color characteristic that the color of the side will be described later as referring to how the difference naneunji the color of the front simulation assessment as applied to the organic light emitting display panel by a formula of the ΔE ^* _ab It can mean a value.

The first retardation film may be a + B plate having an Nz value of Equation 1 less than 0 or a + C plate satisfying the general formula (1). In the case of a + C plate satisfying the general formula 1, since nx = ny, the value of Nz = (nx-nz) / (nx-ny) is not defined.

When the first retardation film is a + B plate, the Nz value may be specifically less than 0, -0.1 or less, -0.2 or less, -0.3 or less, -0.4 or less, or -0.5 or less. Specifically, the lower limit of the Nz value may be -50 or more, -40 or more, -30 or more, or -20 or more. When the Nz value of the first retardation film satisfies the above range, it may be advantageous to realize an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics in front as well as side surfaces.

When the first retardation film is a + B plate, a planar retardation value for light having a wavelength of 550 nm may be 0 nm to 100 nm. The planar retardation value may be specifically 1 nm or more, 2 nm or more, 3 nm or more, 4 nm or more, or 5 nm or more, and may be 100 nm or less, 95 nm or less, 90 nm or less, 85 nm or less, or 80 nm or less. . When the on-plane retardation value of the first retardation film satisfies the above range, it may be advantageous to implement an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics not only on the front side but also on the side surface.

When the first retardation film is a + B plate, the thickness retardation value may be 10 nm to 250 nm. Specifically, the thickness direction retardation value may be 10 nm or more, 20 nm or more, 30 nm or more, or 35 nm or more, and may be 250 nm or less, 240 nm or less, 230 nm or less, or 225 nm or less. When the thickness retardation value of the first retardation film satisfies the above range, it may be advantageous to realize an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics not only on the front side but also on the side surface.

When the first retardation film is a + B plate, the in-plane slow axis may be perpendicular or parallel to the absorption axis of the linear polarizer. This may be advantageous to implement an ultra-high visibility elliptical polarizing plate by showing excellent reflection characteristics and color characteristics from the front as well as the side.

When the first retardation film is a + C plate, the thickness retardation value may be 5 nm to 430 nm. The thickness direction retardation value may be specifically 5 nm or more, 10 nm or more, 20 nm or more, or 30 nm or more, and may be 430 nm or less, 420 nm or less, 410 nm or less, or 400 nm or less. When the thickness retardation value of the first retardation film satisfies the above range, it may be advantageous to realize an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics not only on the front side but also on the side surface.

In the present application may be implemented in the first to third embodiments according to the first retardation film. According to the first embodiment of the present application, the first retardation film may be a + C plate. According to the second embodiment of the present application, the first retardation film may be a + B plate, and the slow axis thereof may be parallel to the absorption axis of the linear polarizer. According to the third embodiment of the present application, the first retardation film may be a + B plate, and the slow axis thereof may be perpendicular to the absorption axis of the linear polarizer.

The second retardation film may be a -B plate with an Nz value greater than one. The Nz value may be specifically 1.15 or more or 1.2 or more. The upper limit of the Nz value may be specifically 20 or less, 15 or less, 10 or less, 8 or less, or 6 or less. When the Nz value of the second retardation film satisfies the above range, it may be advantageous to implement an elliptical polarizing plate having super high visibility by showing excellent reflection and color characteristics in front and side as well.

The planar retardation value for the light of the 550 nm wavelength of the second retardation film may be 5 nm to 130 nm. The planar retardation value may be specifically 5 nm or more, 10 nm or more, 15 nm or more, 20 nm or more, or 25 nm or more, 130 nm or less, 125 nm or less, 120 nm or less, 115 nm or less, or 110 nm or less. . When the on-plane retardation value of the second retardation film satisfies the above range, it may be advantageous to implement an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics not only on the front side but also on the side surface.

The thickness retardation value of the second retardation film may be -220 nm to -5 nm. The thickness direction retardation value may be specifically -220 nm or more, -215 nm or more, or -213 nm or more, and may be -5 nm or less, -10 nm or less, -12 nm or less, or -14 nm or less. When the thickness retardation value of the second retardation film satisfies the above range, it may be advantageous to implement an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics not only on the front side but also on the side surface.

The second retardation film may have an in-plane slow axis parallel to the absorption axis of the linear polarizer. This may be advantageous to implement an ultra-high visibility elliptical polarizing plate by showing excellent reflection characteristics and color characteristics from the front as well as the side.

The total value of the thickness direction retardation of the first retardation film and the phase difference in the thickness direction of the second retardation film may be -20 nm to 200 nm. The total value may be specifically -20 nm or more, -15 nm or more, -10 nm or more, or -5 nm or more, and may be 200 nm or less, 195 nm or less, 190 nm or less, or 187.5 nm or less. This may be advantageous to implement an ultra-high visibility elliptical polarizing plate by showing excellent reflection characteristics and color characteristics from the front as well as the side.

The third retardation film may have an Nz value of 0.8 to 1.2. The third retardation film may be a + B plate, a -B plate, or a + A plate. If the Nz value of the third retardation film is 1.0, it is a + A plate, if it is 0.8 or more and less than 1.0, it is a + B plate close to a + A plate, and if it is more than 1.0 to 1.2 or less, it is a -B plate close to a + A plate.

The third retardation film may have a quarter wavelength phase delay property. In the present specification, the “n wavelength phase retardation characteristic” may mean a characteristic capable of retarding incident light by n times the wavelength of the incident light within at least a portion of a wavelength range. Accordingly, the quarter wavelength phase delay characteristic may mean a characteristic that may phase-retard incident light by 1/4 times the wavelength of the incident light within at least a portion of a wavelength range.

The planar retardation of the third retardation film with respect to light having a wavelength of 550 nm may be 120 nm to 160 nm, specifically 130 nm to 150 nm. When the retardation on the plane of the third retardation film satisfies the above range, it may be advantageous to realize an elliptical polarizing plate having excellent high visibility by displaying excellent reflection characteristics and color characteristics not only on the front side but also on the side surface.

The in-plane slow axis of the third retardation film may form an absorption axis of the linear polarizer about 40 degrees to 50 degrees, about 43 degrees to 47 degrees, and specifically about 45 degrees. This may be advantageous to implement an ultra-high visibility elliptical polarizing plate by showing excellent reflection characteristics and color characteristics from the front as well as the side.

The fourth retardation film may be a + C plate or a + B plate. In the case of the + B plate of the fourth retardation film, the Nz value may be -4.0 or less. When the Nz value of the fourth retardation film is -4.0 or less, it may be a + B plate close to the + C plate. The lower limit of the Nz value of the fourth retardation film may be, for example, -3000 nm or more. When the fourth retardation film is + C plate, nx = ny, so Nz = (nx-nz) / (nx-ny) value may not be defined.

When the fourth retardation film is a + B plate, the in-plane slow axis may be about 40 degrees to 50 degrees, about 43 degrees to 47 degrees, and specifically about 45 degrees with the light absorption axis of the linear polarizer. This may be advantageous to implement an ultra-high visibility elliptical polarizing plate by showing excellent reflection characteristics and color characteristics from the front as well as the side.

The fourth retardation film may have a thickness direction retardation of 0 nm or more. Specifically, the thickness retardation of the fourth retardation film may be 0 nm to 300 nm. More specifically, the thickness retardation of the fourth retardation film may be 0 nm or more, 10 nm or more, 20 nm or more, 30 nm or more, 50 nm or more or 65 nm or more, 300 nm or less, 250 nm or less, 200 nm or less, 150 up to 100 nm, or up to 75 nm. When the thickness retardation of the fourth retardation film satisfies the above range, it may be advantageous to implement an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics not only on the front side but also on the side surface.

The first, second, third to fourth retardation films may have reverse wavelength dispersion characteristics, normal wavelength dispersion characteristics, or flat wavelength dispersion characteristics, respectively. In one example, the first retardation film may have an R (450) / R (550) value of 0.6 to 1.3, or an Rth450 / Rth (550) value of 0.6 to 1.3. In one example, the second retardation film may have an R (450) / R (550) value of 0.6 to 1.3. In one example, the third retardation film may have an R (450) / R (550) value of 0.60 to 1.0, specifically 0.6 to 0.99 or 0.6 to 0.92. R (650) / R (550) value of the third retardation film may have a value larger than the R (450) / R (550) value, it may be 1.01 to 1.19, 1.05 to 1.15 or 1.09 to 1.11. In one example, the fourth retardation film Rth 450 / Rth 550 may be 0.6 to 1.3. In the above, R (λ) means the plane retardation of the retardation film with respect to λnm light, and Rth (λ) means the thickness direction retardation of the retardation film with respect to λnm light. When the wavelength dispersion characteristic of the first, second, third to fourth retardation film is within the above range, it may be advantageous to implement an elliptical polarizing plate having super high visibility by showing excellent reflection characteristics and color characteristics not only in the front but also in the side.

The first, second, third to fourth retardation films may be polymer films or liquid crystal films, respectively. Examples of the polymer film include polyolefins such as PC (polycarbonate), norbonene resin, poly (vinyl alcohol), PVA (polystyrene), PMMA (poly (methyl methacrylate)) and PP (polypropylene), A film including Par (poly (arylate)), PA (polyamide), PET (poly (ethylene terephthalate)) or PS (polysulfone) may be used. The polymer film may be stretched or shrunk under appropriate conditions to impart birefringence to be used as the first to fourth retardation films. The liquid crystal film may include a state in which the liquid crystal molecules are aligned and polymerized. The liquid crystal molecules may be polymerizable liquid crystal molecules. In the present specification, the polymerizable liquid crystal molecule may mean a molecule including a site capable of exhibiting liquid crystal, for example, a mesogen skeleton, and one or more polymerizable functional groups. In addition, including the polymerizable liquid crystal molecules in a polymerized form may mean a state in which the liquid crystal molecules are polymerized to form a skeleton such as a main chain or side chain of the liquid crystal polymer in the liquid crystal film.

The thickness of each of the first, second, third to fourth retardation films may be appropriately adjusted in consideration of the purpose of the present application. For example, the thicknesses of the first, second, third to fourth retardation films may be independently 0.1 μm to 100 μm.

The elliptical polarizing plate may further include a surface treatment layer. An antireflection layer etc. can be illustrated as a surface treatment layer. The surface treatment layer may be disposed outside of the linear polarizer, for example on the opposite side where the first retardation film is disposed. The antireflection layer may be a laminate of two or more layers having different refractive indices, but is not limited thereto.

In the elliptic polarizing plate, the first retardation film, the second retardation film, the third retardation film, the fourth retardation film to the linear polarizer may be attached to each other through an adhesive or an adhesive or may be laminated to each other by direct coating. An optically transparent adhesive or an adhesive can be used as the said adhesive or an adhesive agent.

Since the elliptically polarizing plate of the present application can prevent reflection of external light, the visibility of the organic light emitting device can be improved. Incident unpolarized light (hereinafter referred to as "external light") incident from the outside passes through the linear polarizer and transmits only one of the two polarization orthogonal components, that is, the first polarization orthogonal component, The polarized light may turn into circularly polarized light while passing through the third retardation film. The circularly polarized light is reflected from the display panel of the organic light emitting diode display including the substrate, the electrode, and the like, and the rotation direction of the circularly polarized light is changed, and the circularly polarized light passes through the third retardation film again, and thus the Is converted to the other polarized orthogonal component, that is, the second polarized orthogonal component. Since the second polarized orthogonal component does not pass through the linear polarizer and no light is emitted to the outside, the second polarized orthogonal component may have an external light reflection preventing effect.

In particular, the elliptical polarizing plate of the present application can effectively prevent reflection of external light incident from the side, thereby improving side visibility of the organic light emitting device. For example, the elliptical polarizer of the present application can effectively prevent reflection of external light incident from the side through the viewing angle polarization compensation principle.

 The elliptical polarizing plate of the present application may be applied to an organic light emitting device. 2 is a cross-sectional view illustrating an organic light emitting device to which an elliptical polarizing plate of the present application is applied. Referring to FIG. 2, the organic light emitting device includes an organic light emitting display panel 200 and an elliptically polarizing plate 100 positioned on one surface of the organic light emitting display panel 200. The fourth retardation film 40 of the elliptic polarizer may be disposed adjacent to the organic light emitting display panel 200 as compared to the linear polarizer 50.

The organic light emitting display panel may include a base substrate, a lower electrode, an organic emission layer, an upper electrode, and an encapsulation substrate. One of the lower electrode and the upper electrode may be an anode and the other may be a cathode. The anode may be made of a conductive material having a high work function as an electrode into which holes are injected, and the cathode may be made of a conductive material having a low work function as an electrode into which electrons are injected. At least one of the lower electrode and the upper electrode may be made of a transparent conductive material through which emitted light can come out, and may be, for example, ITO or IZO. The organic light emitting layer may include an organic material that emits light when a voltage is applied to the lower electrode and the upper electrode.

An auxiliary layer may be further included between the lower electrode and the organic light emitting layer and between the upper electrode and the organic light emitting layer. The auxiliary layer may include a hole transporting layer, a hole injecting layer, an electron injecting layer, and an electron transporting layer to balance electrons and holes. However, it is not limited thereto. The encapsulation substrate may be made of glass, metal, and / or polymer, and may encapsulate the lower electrode, the organic emission layer, and the upper electrode to prevent the inflow of moisture and / or oxygen from the outside.

The elliptic polarizer may be disposed on a side from which light is emitted from the organic light emitting display panel. For example, in the case of a bottom emission structure in which light is emitted toward the base substrate, the bottom emission structure may be disposed outside the base substrate. In the case of a top emission structure in which light is emitted to the encapsulation substrate side, the substrate may be disposed outside the encapsulation substrate. have. The elliptically polarizing plate can improve display characteristics of the organic light emitting device by preventing external light from being reflected outside the organic light emitting device by being reflected by a reflective layer made of metal such as electrodes and wirings of the organic light emitting display panel. In addition, since the elliptical polarizing plate may exhibit an anti-reflection effect not only in the front but also in the side as described above, the side visibility may be improved.

The present application can provide an ultra-high visibility elliptical polarizing plate having excellent reflection characteristics and color characteristics in the side as well as the front and an organic light emitting device including the same.

1 is an exemplary cross-sectional view of an elliptical polarizer according to an embodiment of the present application.
2 is a cross-sectional view of an organic light emitting device according to an embodiment of the present application.

Hereinafter, the present application will be described in detail through examples according to the present application and comparative examples according to the present application, but the scope of the present application is not limited to the examples given below.

Evaluation example 1 color  Characteristic simulation evaluation

The color characteristics (Techwiz 1D plus, man system) in the front and side were simulated and evaluated about the Example and the comparative example. Color difference (ΔE ^* _ab , dE) is defined by the following equation.

In the above formula, (L ^* ₁ , a ^* ₁ , b ^* ₁ ) means the reflection color value at the front (an inclination angle of 0 ° and azimuth angle of 0 °), and (L ^* ₂ , a ^* ₂ , b ^* ₂ ) Means the color value of reflection on the side (specific tilt and azimuth). The dE max value was prepared based on the maximum of dE values at an inclination angle of 40 degrees and an azimuth angle of 45 degrees or 135 degrees. The color deviation value (dE value) means how much the color of the side differs from the color of the front. If the value of ΔE ^* _ab is 2.3, it can be regarded as just noticeable difference (JND). If the value of ΔE ^* _ab is less than 2.4, it can be seen that the performance is close to JND.

Example  One

An elliptical polarizing plate including a polarizer, a first retardation film, a second retardation film, a third retardation film, and a fourth retardation film was prepared in sequence, and the elliptical polarizing plate was disposed such that the fourth retardation film was adjacent to the OLED panel.

The polarizer is a linear polarizer having a single transmittance (Ts) of 42.5%, and the OLED panel is a Galaxy S6. The first retardation film is a + C plate, and the second retardation film is a -B plate. The third retardation film has an R (450) / R (550) value of 0.86 and a Rin value of 140 nm, and its slow axis is 45 degrees with the absorption axis of the polarizer. The fourth retardation film is a + C plate having an Rth value of 60 nm. In the above, Rin means a planar retardation value for light of 550nm wavelength of the retardation film, Rth means a thickness direction retardation value for light of 550nm wavelength of the retardation film.

Table 1, Table 2 and Table 3 show the optical properties of the first and second retardation films showing dE Max values less than 2.4 at 40 degree inclination angles when the Nz values of the second retardation film are 1.2, 3.0, and 6.0, respectively. Indicates.

2nd phase difference film First phase difference film First and second
Retardation film dE Max
@ 40 ° tilt angle Nz Rin Rth Rth Rth amount 1.2 70 -14 34 20 2.34 1.2 80 -16 36 20 2.14 1.2 80 -16 46 30 2.20 1.2 90 -18 38 20 2.06 1.2 90 -18 48 30 1.93 1.2 90 -18 58 40 2.04 1.2 90 -18 68 50 2.35 1.2 100 -20 40 20 2.12 1.2 100 -20 50 30 1.85 1.2 100 -20 60 40 1.79 1.2 100 -20 70 50 1.86 1.2 100 -20 80 60 2.15 1.2 110 -22 42 20 2.30 1.2 110 -22 52 30 2.06 1.2 110 -22 62 40 1.94 1.2 110 -22 72 50 1.94 1.2 110 -22 82 60 2.05 1.2 110 -22 92 70 2.23

2nd phase difference film First phase difference film First and second retardation film dE Max
@ 40 ° tilt angle Nz Rin Rth Rth Rth amount 3 35 -70 90 20 2.38 3 35 -70 95 25 2.35 3 40 -80 105 25 2.26 3 40 -80 110 30 2.19 3 40 -80 115 35 2.27 3 45 -90 115 25 2.39 3 45 -90 120 30 2.19 3 45 -90 125 35 2.05 3 45 -90 130 40 2.07 3 45 -90 135 45 2.18 3 45 -90 140 50 2.34 3 50 -100 135 35 2.23 3 50 -100 140 40 2.05 3 50 -100 145 45 1.94 3 50 -100 150 50 1.97 3 50 -100 155 55 2.07 3 50 -100 160 60 2.23 3 55 -110 155 45 2.27 3 55 -110 160 50 2.10 3 55 -110 165 55 1.95 3 55 -110 170 60 1.90 3 55 -110 175 65 1.98 3 55 -110 180 70 2.12 3 55 -110 185 75 2.30 3 60 -120 185 65 2.30 3 60 -120 190 70 2.19 3 60 -120 195 75 2.11 3 60 -120 200 80 2.04 3 60 -120 205 85 2.19 3 60 -120 210 90 2.37

2nd phase difference film First phase difference film First and second retardation film dE Max
@ 40 ° tilt angle Nz Rin Rth Rth Rth amount 6 25 -125 167.5 42.5 2.37 6 25 -125 170 45 2.31 6 25 -125 172.5 47.5 2.31 6 25 -125 175 50 2.34 6 25 -125 177.5 52.5 2.37 6 27.5 -137.5 187.5 50 2.34 6 27.5 -137.5 190 52.5 2.27 6 27.5 -137.5 192.5 55 2.22 6 27.5 -137.5 195 57.5 2.22 6 27.5 -137.5 197.5 60 2.23 6 27.5 -137.5 200 62.5 2.26 6 27.5 -137.5 202.5 65 2.30 6 27.5 -137.5 205 67.5 2.36 6 30 -150 207.5 57.5 2.38 6 30 -150 210 60 2.30 6 30 -150 212.5 62.5 2.22 6 30 -150 215 65 2.15 6 30 -150 217.5 67.5 2.13 6 30 -150 220 70 2.13 6 30 -150 222.5 72.5 2.15 6 30 -150 225 75 2.17 6 30 -150 227.5 77.5 2.21 6 30 -150 230 80 2.26 6 30 -150 232.5 82.5 2.32 6 30 -150 235 85 2.39 6 32.5 -162.5 232.5 70 2.34 6 32.5 -162.5 235 72.5 2.26 6 32.5 -162.5 237.5 75 2.18 6 32.5 -162.5 240 77.5 2.10 6 32.5 -162.5 242.5 80 2.07 6 32.5 -162.5 245 82.5 2.06 6 32.5 -162.5 247.5 85 2.07 6 32.5 -162.5 250 87.5 2.08 6 32.5 -162.5 252.5 90 2.10 6 32.5 -162.5 255 92.5 2.14 6 32.5 -162.5 257.5 95 2.19 6 32.5 -162.5 260 97.5 2.25 6 32.5 -162.5 262.5 100 2.31 6 32.5 -162.5 265 102.5 2.39 6 35 -175 260 85 2.33 6 35 -175 262.5 87.5 2.25 6 35 -175 265 90 2.17 6 35 -175 267.5 92.5 2.10 6 35 -175 270 95 2.03 6 35 -175 272.5 97.5 2.02 6 35 -175 275 100 2.02 6 35 -175 277.5 102.5 2.02 6 35 -175 280 105 2.04 6 35 -175 282.5 107.5 2.07 6 35 -175 285 110 2.10 6 35 -175 287.5 112.5 2.15 6 35 -175 290 115 2.20 6 35 -175 292.5 117.5 2.27 6 35 -175 295 120 2.34 6 37.5 -187.5 290 102.5 2.38 6 37.5 -187.5 292.5 105 2.31 6 37.5 -187.5 295 107.5 2.24 6 37.5 -187.5 297.5 110 2.17 6 37.5 -187.5 300 112.5 2.10 6 37.5 -187.5 302.5 115 2.04 6 37.5 -187.5 305 117.5 2.00 6 37.5 -187.5 307.5 120 2.00 6 37.5 -187.5 310 122.5 2.01 6 37.5 -187.5 312.5 125 2.03 6 37.5 -187.5 315 127.5 2.06 6 37.5 -187.5 317.5 130 2.10 6 37.5 -187.5 320 132.5 2.14 6 37.5 -187.5 322.5 135 2.19 6 37.5 -187.5 325 137.5 2.25 6 37.5 -187.5 327.5 140 2.32 6 37.5 -187.5 330 142.5 2.39 6 40 -200 330 130 2.35 6 40 -200 332.5 132.5 2.29 6 40 -200 335 135 2.23 6 40 -200 337.5 137.5 2.18 6 40 -200 340 140 2.13 6 40 -200 342.5 142.5 2.08 6 40 -200 345 145 2.04 6 40 -200 347.5 147.5 2.06 6 40 -200 350 150 2.09 6 40 -200 352.5 152.5 2.13 6 40 -200 355 155 2.17 6 40 -200 357.5 157.5 2.22 6 40 -200 360 160 2.27 6 40 -200 362.5 162.5 2.33 6 40 -200 365 165 2.40 6 42.5 -212.5 380 167.5 2.38 6 42.5 -212.5 382.5 170 2.34 6 42.5 -212.5 385 172.5 2.31 6 42.5 -212.5 387.5 175 2.27 6 42.5 -212.5 390 177.5 2.24 6 42.5 -212.5 392.5 180 2.23 6 42.5 -212.5 395 182.5 2.28 6 42.5 -212.5 397.5 185 2.32 6 42.5 -212.5 400 187.5 2.38

Example  2

The same structure as that in Example 1 was set except that the first retardation film and the second retardation film were changed as follows.

The first retardation film is a + B plate whose slow axis is parallel to the absorption axis of the polarizer. The second retardation film is a -B plate, whose slow axis is parallel to the absorption axis of the polarizer.

Table 4 and Table 5 show the optical properties of the first and second retardation film showing a dE Max value of less than 2.4 at a 40 degree inclination angle, respectively, when the Nz values of the second retardation film are 1.2 and 6.0, respectively.

2nd phase difference film First phase difference film First and second retardation film dE Max
@ 40 ° tilt angle Nz Rin Rth Nz Rin Rth Rth amount 1.2 100 -20 -1.5 20.0 50 30 2.39 1.2 100 -20 -1.5 22.0 55 35 2.34 1.2 100 -20 -1.5 24.0 60 40 2.34 1.2 100 -20 -1.5 26.0 65 45 2.37 1.2 100 -20 -2 16.7 50 30 2.33 1.2 100 -20 -2 18.3 55 35 2.27 1.2 100 -20 -2 20.0 60 40 2.25 1.2 100 -20 -2 21.7 65 45 2.27 1.2 100 -20 -2 23.3 70 50 2.33 1.2 100 -20 -2.5 12.9 45 25 2.39 1.2 100 -20 -2.5 14.3 50 30 2.29 1.2 100 -20 -2.5 15.7 55 35 2.22 1.2 100 -20 -2.5 17.1 60 40 2.21 1.2 100 -20 -2.5 18.6 65 45 2.21 1.2 100 -20 -2.5 20.0 70 50 2.26 1.2 100 -20 -2.5 21.4 75 55 2.35 1.2 100 -20 -3 11.3 45 25 2.36 1.2 100 -20 -3 12.5 50 30 2.26 1.2 100 -20 -3 13.8 55 35 2.19 1.2 100 -20 -3 15.0 60 40 2.20 1.2 100 -20 -3 16.3 65 45 2.20 1.2 100 -20 -3 17.5 70 50 2.21 1.2 100 -20 -3 18.8 75 55 2.29 1.2 100 -20 -3.5 10.0 45 25 2.34 1.2 100 -20 -3.5 11.1 50 30 2.24 1.2 100 -20 -3.5 12.2 55 35 2.18 1.2 100 -20 -3.5 13.3 60 40 2.19 1.2 100 -20 -3.5 14.4 65 45 2.19 1.2 100 -20 -3.5 15.6 70 50 2.20 1.2 100 -20 -3.5 16.7 75 55 2.26 1.2 100 -20 -3.5 17.8 80 60 2.37 1.2 100 -20 -4 9.0 45 25 2.33 1.2 100 -20 -4 10.0 50 30 2.22 1.2 100 -20 -4 11.0 55 35 2.18 1.2 100 -20 -4 12.0 60 40 2.18 1.2 100 -20 -4 13.0 65 45 2.19 1.2 100 -20 -4 14.0 70 50 2.19 1.2 100 -20 -4 15.0 75 55 2.24 1.2 100 -20 -4.5 8.2 45 25 2.32 1.2 100 -20 -4.5 9.1 50 30 2.21 1.2 100 -20 -4.5 10.0 55 35 2.17 1.2 100 -20 -4.5 10.9 60 40 2.18 1.2 100 -20 -4.5 11.8 65 45 2.18 1.2 100 -20 -4.5 12.7 70 50 2.19 1.2 100 -20 -4.5 13.6 75 55 2.26 1.2 100 -20 -5 7.5 45 25 2.31 1.2 100 -20 -5 8.3 50 30 2.20 1.2 100 -20 -5 9.2 55 35 2.17 1.2 100 -20 -5 10.0 60 40 2.17 1.2 100 -20 -5 10.8 65 45 2.18 1.2 100 -20 -5 11.7 70 50 2.18 1.2 100 -20 -5 12.5 75 55 2.28

2nd phase difference film First phase difference film First and second retardation film dE Max
@ 40 ° tilt angle Nz Rin Rth Nz Rin Rth Rth amount 6 37.5 -187.5 -9 20.3 202.5 15 2.37 6 37.5 -187.5 -10 17.5 192.5 5 2.39 6 37.5 -187.5 -10 18.0 197.5 10 2.27 6 37.5 -187.5 -10 18.4 202.5 15 2.27 6 37.5 -187.5 -11 16.0 192.5 5 2.28 6 37.5 -187.5 -11 16.5 197.5 10 2.17 6 37.5 -187.5 -11 16.9 202.5 15 2.25 6 37.5 -187.5 -12 14.4 187.5 0 2.38 6 37.5 -187.5 -12 14.8 192.5 5 2.19 6 37.5 -187.5 -12 15.2 197.5 10 2.08 6 37.5 -187.5 -12 15.6 202.5 15 2.23 6 37.5 -187.5 -13 13.4 187.5 0 2.31 6 37.5 -187.5 -13 13.8 192.5 5 2.12 6 37.5 -187.5 -13 14.1 197.5 10 2.02 6 37.5 -187.5 -13 14.5 202.5 15 2.22 6 37.5 -187.5 -14 12.5 187.5 0 2.25 6 37.5 -187.5 -14 12.8 192.5 5 2.06 6 37.5 -187.5 -14 13.2 197.5 10 2.01 6 37.5 -187.5 -14 13.5 202.5 15 2.22 6 37.5 -187.5 -15 11.7 187.5 0 2.20 6 37.5 -187.5 -15 12.0 192.5 5 2.01 6 37.5 -187.5 -15 12.3 197.5 10 2.00 6 37.5 -187.5 -15 12.7 202.5 15 2.21 6 37.5 -187.5 -16 11.0 187.5 0 2.15 6 37.5 -187.5 -16 11.3 192.5 5 1.97 6 37.5 -187.5 -16 11.6 197.5 10 2.00 6 37.5 -187.5 -16 11.9 202.5 15 2.21 6 37.5 -187.5 -17 10.1 182.5 -5 2.38 6 37.5 -187.5 -17 10.4 187.5 0 2.12 6 37.5 -187.5 -17 10.7 192.5 5 1.94 6 37.5 -187.5 -17 11.0 197.5 10 1.99 6 37.5 -187.5 -17 11.3 202.5 15 2.21 6 37.5 -187.5 -18 9.6 182.5 -5 2.35 6 37.5 -187.5 -18 9.9 187.5 0 2.09 6 37.5 -187.5 -18 10.1 192.5 5 1.91 6 37.5 -187.5 -18 10.4 197.5 10 1.99 6 37.5 -187.5 -18 10.7 202.5 15 2.21 6 37.5 -187.5 -19 9.1 182.5 -5 2.32 6 37.5 -187.5 -19 9.4 187.5 0 2.06 6 37.5 -187.5 -19 9.6 192.5 5 1.91 6 37.5 -187.5 -19 9.9 197.5 10 1.98 6 37.5 -187.5 -19 10.1 202.5 15 2.21 6 37.5 -187.5 -20 8.7 182.5 -5 2.30 6 37.5 -187.5 -20 8.9 187.5 0 2.04 6 37.5 -187.5 -20 9.2 192.5 5 1.90 6 37.5 -187.5 -20 9.4 197.5 10 1.98 6 37.5 -187.5 -20 9.6 202.5 15 2.21

Example  3

The same structure as that in Example 1 was set except that the first retardation film and the second retardation film were changed as follows.

The first retardation film is a + B plate whose slow axis is perpendicular to the absorption axis of the polarizer. The second retardation film is a -B plate, whose slow axis is parallel to the absorption axis of the polarizer.

Tables 6 and 7 show the optical properties of the first and second retardation films showing dE Max values of less than 2.4 at 40 degree tilt angles when the Nz values of the second retardation films are 1.2 and 6.0, respectively.

2nd phase difference film First phase difference film First and second retardation film dE Max
@ 40 ° tilt angle Nz Rin Rth Nz Rin Rth Rth amount 1.2 100 -20 -0.5 60.0 90 70 2.38 1.2 100 -20 -0.5 63.3 95 75 2.36 1.2 100 -20 -0.5 66.7 100 80 2.36 1.2 100 -20 -0.5 70.0 105 85 2.37 1.2 100 -20 -0.5 73.3 110 90 2.39 1.2 100 -20 -One 32.5 65 45 2.34 1.2 100 -20 -One 35.0 70 50 2.25 1.2 100 -20 -One 37.5 75 55 2.21 1.2 100 -20 -One 40.0 80 60 2.20 1.2 100 -20 -One 42.5 85 65 2.21 1.2 100 -20 -One 45.0 90 70 2.25 1.2 100 -20 -One 47.5 95 75 2.32 1.2 100 -20 -1.5 22.0 55 35 2.40 1.2 100 -20 -1.5 24.0 60 40 2.28 1.2 100 -20 -1.5 26.0 65 45 2.18 1.2 100 -20 -1.5 28.0 70 50 2.14 1.2 100 -20 -1.5 30.0 75 55 2.14 1.2 100 -20 -1.5 32.0 80 60 2.17 1.2 100 -20 -1.5 34.0 85 65 2.24 1.2 100 -20 -1.5 36.0 90 70 2.35 1.2 100 -20 -2 18.3 55 35 2.30 1.2 100 -20 -2 20.0 60 40 2.19 1.2 100 -20 -2 21.7 65 45 2.11 1.2 100 -20 -2 23.3 70 50 2.10 1.2 100 -20 -2 25.0 75 55 2.14 1.2 100 -20 -2 26.7 80 60 2.21 1.2 100 -20 -2 28.3 85 65 2.32 1.2 100 -20 -2.5 14.3 50 30 2.36 1.2 100 -20 -2.5 15.7 55 35 2.23 1.2 100 -20 -2.5 17.1 60 40 2.13 1.2 100 -20 -2.5 18.6 65 45 2.08 1.2 100 -20 -2.5 20.0 70 50 2.10 1.2 100 -20 -2.5 21.4 75 55 2.15 1.2 100 -20 -2.5 22.9 80 60 2.26 1.2 100 -20 -2.5 24.3 85 65 2.40 1.2 100 -20 -3 12.5 50 30 2.32 1.2 100 -20 -3 13.8 55 35 2.19 1.2 100 -20 -3 15.0 60 40 2.10 1.2 100 -20 -3 16.3 65 45 2.07 1.2 100 -20 -3 17.5 70 50 2.10 1.2 100 -20 -3 18.8 75 55 2.18 1.2 100 -20 -3 20.0 80 60 2.30 1.2 100 -20 -3.5 11.1 50 30 2.28 1.2 100 -20 -3.5 12.2 55 35 2.16 1.2 100 -20 -3.5 13.3 60 40 2.08 1.2 100 -20 -3.5 14.4 65 45 2.06 1.2 100 -20 -3.5 15.6 70 50 2.11 1.2 100 -20 -3.5 16.7 75 55 2.20 1.2 100 -20 -3.5 17.8 80 60 2.34 1.2 100 -20 -4 10.0 50 30 2.26 1.2 100 -20 -4 11.0 55 35 2.14 1.2 100 -20 -4 12.0 60 40 2.06 1.2 100 -20 -4 13.0 65 45 2.06 1.2 100 -20 -4 14.0 70 50 2.12 1.2 100 -20 -4 15.0 75 55 2.23 1.2 100 -20 -4 16.0 80 60 2.38 1.2 100 -20 -4.5 8.2 45 25 2.38 1.2 100 -20 -4.5 9.1 50 30 2.24 1.2 100 -20 -4.5 10.0 55 35 2.13 1.2 100 -20 -4.5 10.9 60 40 2.06 1.2 100 -20 -4.5 11.8 65 45 2.06 1.2 100 -20 -4.5 12.7 70 50 2.13 1.2 100 -20 -4.5 13.6 75 55 2.25 1.2 100 -20 -5 7.5 45 25 2.37 1.2 100 -20 -5 8.3 50 30 2.22 1.2 100 -20 -5 9.2 55 35 2.11 1.2 100 -20 -5 10.0 60 40 2.07 1.2 100 -20 -5 10.8 65 45 2.07 1.2 100 -20 -5 11.7 70 50 2.14 1.2 100 -20 -5 12.5 75 55 2.26

2nd phase difference film First phase difference film First and second retardation film dE Max
@ 40 ° tilt angle Nz Rin Rth Nz Rin Rth Rth amount 6 37.5 -187.5 -7 25.9 207.5 20 2.33 6 37.5 -187.5 -7 26.6 212.5 25 2.36 6 37.5 -187.5 -8 22.5 202.5 15 2.28 6 37.5 -187.5 -8 23.1 207.5 20 2.23 6 37.5 -187.5 -8 23.6 212.5 25 2.30 6 37.5 -187.5 -9 19.8 197.5 10 2.32 6 37.5 -187.5 -9 20.3 202.5 15 2.18 6 37.5 -187.5 -9 20.8 207.5 20 2.17 6 37.5 -187.5 -9 21.3 212.5 25 2.29 6 37.5 -187.5 -10 18.0 197.5 10 2.22 6 37.5 -187.5 -10 18.4 202.5 15 2.12 6 37.5 -187.5 -10 18.9 207.5 20 2.14 6 37.5 -187.5 -10 19.3 212.5 25 2.29 6 37.5 -187.5 -11 16.0 192.5 5 2.35 6 37.5 -187.5 -11 16.5 197.5 10 2.15 6 37.5 -187.5 -11 16.9 202.5 15 2.07 6 37.5 -187.5 -11 17.3 207.5 20 2.13 6 37.5 -187.5 -11 17.7 212.5 25 2.31 6 37.5 -187.5 -12 14.8 192.5 5 2.28 6 37.5 -187.5 -12 15.2 197.5 10 2.10 6 37.5 -187.5 -12 15.6 202.5 15 2.04 6 37.5 -187.5 -12 16.0 207.5 20 2.12 6 37.5 -187.5 -12 16.3 212.5 25 2.34 6 37.5 -187.5 -13 13.8 192.5 5 2.22 6 37.5 -187.5 -13 14.1 197.5 10 2.06 6 37.5 -187.5 -13 14.5 202.5 15 2.02 6 37.5 -187.5 -13 14.8 207.5 20 2.13 6 37.5 -187.5 -13 15.2 212.5 25 2.36 6 37.5 -187.5 -14 12.8 192.5 5 2.18 6 37.5 -187.5 -14 13.2 197.5 10 2.02 6 37.5 -187.5 -14 13.5 202.5 15 2.01 6 37.5 -187.5 -14 13.8 207.5 20 2.14 6 37.5 -187.5 -14 14.2 212.5 25 2.39 6 37.5 -187.5 -15 11.7 187.5 0 2.38 6 37.5 -187.5 -15 12.0 192.5 5 2.14 6 37.5 -187.5 -15 12.3 197.5 10 2.00 6 37.5 -187.5 -15 12.7 202.5 15 2.00 6 37.5 -187.5 -15 13.0 207.5 20 2.15 6 37.5 -187.5 -16 11.0 187.5 0 2.34 6 37.5 -187.5 -16 11.3 192.5 5 2.10 6 37.5 -187.5 -16 11.6 197.5 10 1.98 6 37.5 -187.5 -16 11.9 202.5 15 2.00 6 37.5 -187.5 -16 12.2 207.5 20 2.16 6 37.5 -187.5 -17 10.4 187.5 0 2.31 6 37.5 -187.5 -17 10.7 192.5 5 2.08 6 37.5 -187.5 -17 11.0 197.5 10 1.96 6 37.5 -187.5 -17 11.3 202.5 15 2.00 6 37.5 -187.5 -17 11.5 207.5 20 2.17 6 37.5 -187.5 -18 9.9 187.5 0 2.28 6 37.5 -187.5 -18 10.1 192.5 5 2.05 6 37.5 -187.5 -18 10.4 197.5 10 1.95 6 37.5 -187.5 -18 10.7 202.5 15 2.00 6 37.5 -187.5 -18 10.9 207.5 20 2.19 6 37.5 -187.5 -19 9.4 187.5 0 2.25 6 37.5 -187.5 -19 9.6 192.5 5 2.03 6 37.5 -187.5 -19 9.9 197.5 10 1.94 6 37.5 -187.5 -19 10.1 202.5 15 2.00 6 37.5 -187.5 -19 10.4 207.5 20 2.20 6 37.5 -187.5 -20 8.9 187.5 0 2.23 6 37.5 -187.5 -20 9.2 192.5 5 2.02 6 37.5 -187.5 -20 9.4 197.5 10 1.93 6 37.5 -187.5 -20 9.6 202.5 15 2.00 6 37.5 -187.5 -20 9.9 207.5 20 2.21

Comparative example  One

The same structure as Example 1 was set except that the elliptical polarizing plate including the polarizer, the third retardation film, and the fourth retardation film was not sequentially included without including the first retardation film and the second retardation film. The dE max value of Comparative Example 1 was 2.8.

10: first retardation film
20: second retardation film
30: third retardation film
40: fourth retardation film
50: line polarizer
100: elliptical polarizer
200: organic light emitting display panel

Claims (18)

A linear polarizer, a first retardation film, a second retardation film, a third retardation film, and a fourth retardation film in sequence,
The first retardation film is a + B plate having an Nz value of Equation 1 below 0 or a + C plate satisfying the following general formula 1,
The second retardation film is a -B plate having an Nz value of Equation 1 below 1,
In the third retardation film, the Nz value of Equation 1 is 0.8 to 1.2, and the in-plane slow axis is 43 to 47 degrees with the absorption axis of the linear polarizer.
The fourth retardation film is a + B plate having an Nz value of Equation 1 below -4.0 or below, or + C plate satisfying the following general formula 1,
The total value of the thickness direction retardation of the first retardation film and the phase difference in the thickness direction of the second retardation film is -20 nm to 200 nm, and the thickness direction retardation (Rth) is an elliptical polarizing plate defined by Equation 2 below:
[Equation 1]
Nz = (nx-nz) / (nx-ny)
[Formula 2]
Rth = (nz-ny) × d
[Formula 1]
nx = ny <nz
In formulas 1 to 2 and general formula 1, nx, ny, and nz are refractive indices in the x-axis, y-axis, and z-axis directions of the retardation film, respectively, and the x-axis is a direction parallel to the in-plane slow axis of the retardation film. , the y axis is a direction parallel to the in-plane fast axis of the retardation film, the z axis is the thickness direction of the retardation film, and d is the thickness of the retardation film. The elliptic polarizing plate of claim 1, wherein the first retardation film is a + B plate, and the Nz value is -0.5 or less. The elliptically polarizing plate of claim 1, wherein the first retardation film is a + B plate, and an in-plane retardation value for light having a wavelength of 550 nm is 0 nm to 100 nm. The elliptic polarizing plate of claim 1, wherein the first retardation film is a + B plate, and the thickness retardation value is 10 nm to 250 nm. The elliptic polarizing plate of claim 1, wherein the first retardation film is a + B plate, and an in-plane slow axis is perpendicular or parallel to an absorption axis of the linear polarizer. The elliptical polarizing plate of claim 1, wherein the first retardation film is a + C plate, and the thickness retardation value is 5 nm to 430 nm. The method of claim 1, wherein R (450) / R (550) of the first retardation film is 0.6 to 1.3, or Rth (450) / Rth (550) is 0.6 to 1.3, and R (λ) is applied to λ nm light. The elliptical polarizing plate which means the surface retardation of the retardation film with respect to, and Rth ((lambda)) means the thickness direction retardation of the retardation film with respect to (lambda) nm light. The elliptical polarizing plate of claim 1, wherein the Nz value of the second retardation film is 1.2 to 6. The elliptical polarizing plate of claim 1, wherein the planar retardation of the second retardation film with respect to light having a wavelength of 550 nm is 5 nm to 130 nm. The elliptical polarizing plate of claim 1, wherein the thickness retardation value of the second retardation film is -220 nm to -5 nm. The elliptical polarizing plate of claim 1, wherein the second retardation film has an in-plane slow axis parallel to an absorption axis of the linear polarizer. The elliptical polarizing plate according to claim 1, wherein R (450) / R (550) of the second retardation film is 0.6 to 1.3, and R (λ) means a planar phase difference of the retardation film with respect to λ nm light. The elliptical polarizing plate of claim 1, wherein the planar retardation of the third retardation film with respect to light having a wavelength of 550 nm is 130 nm to 150 nm. The elliptical polarizing plate according to claim 1, wherein R (450) / R (550) of the third retardation film is 0.6 to 1.0, and R (λ) means a planar phase difference of the retardation film with respect to λ nm light. The elliptically polarizing plate of claim 1, wherein the thickness retardation of the fourth retardation film is 0 nm to 300 nm. The elliptical polarizing plate of claim 1, wherein Rth (450) / Rth (550) of the fourth retardation film is 0.6 to 1.3, and Rth (λ) is a thickness direction retardation of the retardation film with respect to λ nm light. An organic light emitting device comprising the elliptic polarizing plate of claim 1 and an organic light emitting display panel. 18. The organic light emitting device of claim 17, wherein the fourth retardation film of the elliptical polarizing plate is disposed adjacent to the organic light emitting display panel compared to the linear polarizer.

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